$ \newcommand{\braket}[1]{\langle #1 \rangle} \newcommand{\abs}[2][]{\left\lvert#2\right\rvert_{\text{#1}}} \newcommand{\ket}[1]{\left\lvert#1 \right.\rangle} \newcommand{\bra}[1]{\langle\left. #1\right\rvert} \newcommand{\braket}[1]{\langle #1 \rangle} \newcommand{\dd}{\text{d}} \newcommand{\dv}[2]{\frac{\dd #1}{\dd #2}} \newcommand{\pdv}[2]{\frac{\partial}{\partial #1}} $
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Every Linear Transformation can be Represented as a Matrix

Every lnear transformation on $T:\mathbb{F}^n\to\mathbb{F}^n$ is of the form $Tx=Ax$ for some $m/times n$ matrix $A$.

Concepts

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Hypothesis

Coming soon

Results

Coming soon

Proof

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Every Linear Transformation can be Represented as a Matrix

Every lnear transformation on $T:\mathbb{F}^n\to\mathbb{F}^n$ is of the form $Tx=Ax$ for some $m/times n$ matrix $A$.

Concepts

Coming soon

Hypothesis

Coming soon

Results

Coming soon

Proof

Coming soon
FullPage
result
concepts
hypothesis
implications
proof
FullPage
result
concepts
hypothesis
implications
proof

Every Linear Transformation can be Represented as a Matrix

Every lnear transformation on $T:\mathbb{F}^n\to\mathbb{F}^n$ is of the form $Tx=Ax$ for some $m/times n$ matrix $A$.

Concepts

Coming soon

Hypothesis

Coming soon

Results

Coming soon

Proof

Coming soon

Every Linear Transformation can be Represented as a Matrix

Every lnear transformation on $T:\mathbb{F}^n\to\mathbb{F}^n$ is of the form $Tx=Ax$ for some $m/times n$ matrix $A$.

Concepts

Coming soon

Hypothesis

Coming soon

Results

Coming soon

Proof

Coming soon
FullPage
result
concepts
hypothesis
implications
proof